BR112017016185B1 - INTRAOCULAR LENS INJECTOR - Google Patents

Abstract

INTRAOCULAR LENS INJECTOR. Apparatus, systems and methods for implanting an intraocular lens in an eye are described. For example, an intraocular lens injector may include a plunger and an injector body that includes an insertion depth shield and a nozzle extending therefrom. The insertion depth guard is disposed at a distal end of the injector body to limit the distance that the nozzle penetrates into the eye. The intraocular lens injector may also include a tilting element configured to generate a counterforce to distal movement of the plunger through the injector rod. An exemplary intraocular lens injector may include a tilting member to produce a counterforce that opposes advancement of the plunger through the injector body. Counterforce provides more continuous plunger advancement while substantially reducing or eliminating sudden changes in the rate at which the plunger is advanced through the injector body.

Description

CROSS REFERENCE TO RELATED ORDERS

[0001] This application claims the benefit of the Interim Application in U.S.62/128,356, filed March 4, 2015, and claims the benefit of the Interim Application in U.S.62/208,064, filed on August 21, 2015, the entire contents of which are included in this document by way of reference.

FIELD OF TECHNIQUE

[0002] The present description relates to systems, apparatus and methods for intraocular lens injectors.

BACKGROUND

[0003] The human eye, in its simplest concept, functions to provide vision by transmitting and refracting light through a clear outer portion called the cornea, and further focusing the image through the lens onto the retina at the back of the eye. . The quality of the focused image depends on several factors including the size, shape and length of the eye, and the shape and transparency of the cornea and lens. When trauma, age or illness causes the lens to become less transparent, vision deteriorates due to the diminished light that can be transmitted to the retina. This deficiency in the lens of the eye is medically known as a cataract. Treatment for this condition is surgical removal of the lens and implementation of an artificial intraocular lens (“IOL”).

[0004] Many cataract lenses are removed by a surgical technique called phacoemulsification. During this procedure, an opening is made in the anterior capsule and a fine phacoemulsification cutting tip is inserted into the diseased lens and vibrated ultrasonically. The vibrating cutting tip liquefies or emulsifies the lens so that the lens can be aspirated out of the eye. The diseased lens, once removed, is replaced with an artificial lens.

[0005] The IOL is injected into the eye through the same small incision used to remove the diseased lens. An IOL injector is used to deliver an IOL into the eye.

SUMMARY

[0006] According to one aspect, the description describes an intraocular lens injector which may include an injector body, and a plunger slidable within a hole formed in the injector body. The injector body may include the hole, an interior wall defining the hole, an insertion depth guard disposed at a distal end of the injector body, and a nozzle distally extending beyond the insertion depth guard. Insertion depth protection can include a flanged surface.

[0007] Another aspect of the description encompasses an intraocular lens injector. The intraocular lens injector may include an injector body and a plunger. The nozzle body may include a hole defined by an interior wall and a nozzle formed at a distal end of the nozzle body. The plunger may be slidable into the bore and may include a plunger tip. The tip may include a first groove and a second groove located within the first groove.

[0008] Another aspect of the description encompasses an intraocular lens injector that includes an injector body and a plunger. The nozzle body includes a hole defined by an interior wall and a nozzle formed at a distal end of the nozzle body. The plunger is slidable in the bore and includes a plunger tip and a longitudinal axis. The plunger tip includes a first protrusion extending distally from a first side of the plunger tip and a hinge disposed at a proximal end of the first protrusion. The first protrusion extends at an oblique angle relative to the longitudinal axis and pivots around the joint.

[0009] The various aspects may include one or more of the following features. The flanged surface may be a curved surface. The curved surface may be a spherical surface. The plunger may include a body portion and a biasing member disposed adjacent a proximal end of the body portion. The tilting element may be deformable by engaging the nozzle body to produce a resistive force for further advancement of the plunger through the bore. The biasing member may include a channel, and wherein the body portion of the plunger may extend through the channel. The nozzle body may include a tab formed at a proximal end thereof, a groove extending through the tab, and a hole aligned with the groove. The intraocular lens injector may also include a plunger stop. The plunger stop may include a protrusion. The plunger stop may be removably received in the groove so that the protrusion extends through the bore and into a gap formed in the plunger. The plunger may include a centilever member. The hole may include a shoulder, and the hole formed in the nozzle body may align with the gap formed in the plunger when the centilever member engages the shoulder.

[0010] The various aspects may also include one or more of the following features. The injector body may include a compartment in communication with the bore. Housing and hole can be mated together in an interface. The interior wall may include a tapered portion defining an opening that provides communication between the hole and the housing. The inner wall may include a flexible wall portion disposed in the opening. The plunger may include a plunger rod, and the housing may include a receiving surface adapted to receive an intraocular lens. The receiving surface may include a contour ramp disposed distally from the opening. The flexible wall portion may be configured to align the piston rod within the opening. The contour ramp can be configured to deflect the piston rod in a second direction opposite the first direction as the piston rod is advanced through the housing. The plunger may include a centilever member, and the centilever member may deflectively engage the interior wall of the bore as the plunger is advanced through the bore.

[0011] The various aspects may include one or more of the following features. The second groove may be formed at a first end of the first groove. A second end of the first groove opposite the first end may be configured to capture a posterior haptic portion of an intraocular lens disposed in the injector body, and the second groove may be adapted to capture a proximal end of an optical portion of the intraocular lens. The piston may include a piston rod, and at least a portion of the piston rod may be angularly offset from a longitudinal axis of the piston rod. The injector body may include an insertion depth guard disposed at a distal end of the injector body, and the insertion depth guard may include a flanged surface. A cross-sectional dimension of the insertion depth guard may be larger than a cross-sectional dimension of the nozzle. The flanged surface may be a curved surface. The plunger may include a biasing member disposed adjacent a proximal end of the plunger. The tilting element can be deformable by engaging the nozzle body to produce a resistive force to further advance the plunger through the bore. The biasing member may include a channel, and wherein the body portion of the plunger may extend through the channel. A first groove may be disposed adjacent a second protrusion and adapted to receive an optical portion of an intraocular lens.

[0012] It is to be understood that both the aforementioned general description and the following detailed description are exemplary and explanatory in nature and are intended to provide an understanding of the present description without limiting the scope of the present description. In this regard, the additional aspects, features and advantages of the present disclosure will be apparent to a person skilled in the art from the following detailed description.

BRIEF DESCRIPTION OF THE DRAWINGS

[0013] Figure 1 is a perspective view of an exemplary intraocular lens injector.

[0014] Figure 2 shows a longitudinal cross-sectional view of the intraocular lens injector of Figure 1.

[0015] Figure 3 is a perspective view of a distal portion of an exemplary injector body of the intraocular lens injector of Figure 1.

[0016] Figure 4 is a cross-sectional view of the distal portion of the injector body shown in Figure 3.

[0017] Figure 5 is an exemplary cross-sectional format of an intraocular lens injector nozzle.

[0018] Figure 6 shows an intraocular lens injector partially inserted into one eye.

[0019] Figure 7 shows a construction method for defining a flanged surface of an insertion depth shield of an exemplary intraocular lens injector.

[0020] Figure 8 shows a cross-sectional view of a compartment that receives an intraocular lens formed in an injector body.

[0021] Figure 9 shows a perspective view of a compartment that receives an intraocular lens formed in an injector body.

[0022] Figure 10 is a cross-sectional view of a piston.

[0023] Figure 11 is a bottom view of a piston.

[0024] Figure 12 is a partial perspective view showing tabs and a plunger lock of an exemplary intraocular lens injector.

[0025] Figure 13 is a detailed view of an exemplary plunger tip.

[0026] Figure 14 shows an exemplary interior surface of a port surrounding a lens-receiving compartment of an intraocular lens injector.

[0027] Figure 15 shows deformation suffered by an exemplary spring during the advancement of a plunger of an intraocular lens injector.

[0028] Figure 16 is a detailed view of a plunger with another example tilt element design.

[0029] Figure 17 illustrates a piston that has yet another exemplary tilt element design.

[0030] Figure 18 shows another plunger with an additional exemplary tilt element design.

[0031] Figure 19 is a detailed view of the distal end of the IOL injector showing a demarcation designating a pause position of an IOL advancing through the IOL injector.

[0032] Figure 20 is a view of a distal end 60 of an IOL injector with an IOL located therein in a paused position.

[0033] Figure 21 is a detailed view of an exemplary IOL injector showing an opening at an interface between a housing in which an IOL is received and an internal hole of an injector body, where the detailed view is transverse to a longitudinal axis of the IOL injector, and wherein the detail view shows a flexible wall portion in contact with an injector rod.

[0034] Figure 22 is a partial cross-sectional view of an exemplary IOL injector.

[0035] Figures 23 to 24 show an exemplary feed stop coupled to a piston.

[0036] Figures 25 to 26 show another exemplary feed stop coupled to a piston.

[0037] Figure 27 shows an example IOL.

[0038] Figure 28 is a perspective view of an exemplary plunger tip.

[0039] Figure 29 is a side view of the exemplary plunger tip of Figure 28.

[0040] Figure 30 is a top view of the exemplary plunger tip of Figure 28.

DETAILED DESCRIPTION

[0041] For the purposes of generating an understanding of the principles of the present description, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will, however, be understood that no limitation of the scope of the description is intended. Any further changes and modifications to the devices, instruments, methods described and any further application of the principles of the present description are fully contemplated as would normally occur to a person skilled in the art to which the description pertains. In particular, it is fully contemplated that features, components, and/or steps described with respect to one implementation may be combined with features, components, and/or steps described with respect to other implementations of the present disclosure.

[0042] The present description pertains to systems, apparatus and methods for delivering an IOL to an eye. Figures 1 and 2 show an exemplary IOL injector 10 that includes an injector body 20 and a plunger 30. The injector body 20 defines a hole 40 that extends from a proximal end 50 of the injector body 20 to a distal end 60 of injector body 20. Plunger 30 is slidable into hole 40. Particularly, plunger 30 is slidable into hole 40 in order to advance an IOL, such as IOL 70, into injector body 20. IOL injector 10 also includes a longitudinal axis 75. Longitudinal axis 75 may extend along plunger 30 and define a longitudinal axis of plunger 30.

[0043] Injector body 20 includes a housing 80 operable to house an IOL prior to insertion into an eye. In some examples, a door 90 may be included to provide access to compartment 80. Door 90 may include a hinge 100 so that door 90 can be pivoted about hinge 100 to open compartment 80. Injector body 20 may also include tabs 110 formed at proximal end 50 of nozzle body 20. Tabs 110 may be manipulated by the fingers of a user, such as an ophthalmologist or other medical professional, to advance plunger 30 through bore 40.

[0044] Figures 3 to 5 illustrate details of the distal end 60 of the nozzle body 20. In some examples, the distal end 60 has a tapered outer surface. In addition, the distal end 60 includes a hole 64 that tapers toward a distal opening 125. The nozzle body 20 also includes a nozzle 120 at the distal end 60. The nozzle 120 is adapted for insertion into an eye so that an IOL can be deployed. An IOL is expelled from the distal opening 125 formed in the nozzle 120. As shown in Figure 5, the nozzle 120 may have an elliptical cross-section. Additionally, nozzle 120 may include a beveled tip 130. Housing 80, orifice 64 and aperture 125 may define a dispensing orifice 127. A size of dispensing orifice 127 may vary along its length. That is, in some examples, a height H1 of the orifice may change along a length of the delivery hole 127. The variation in size of the delivery hole 127 can contribute to the bending of the IOL as it is advanced along the along this one.

[0045] In some examples, the nozzle body 20 may include an insertion depth guard 140. The insertion depth guard 140 may form a flanged surface 150 which is adapted to be in contiguity with an outer eye surface. Insertion depth guard 140 is in contiguity with an eye surface and thus limits an amount by which the nozzle 120 is allowed to extend into an eye. In some implementations, the flanged surface 150 may have a curvature that conforms to the outer surface of an eye. For example, flanged surface 150 may have a curvature that conforms to a sclera surface of the eye. In other examples, the flanged surface 150 may have a curvature that corresponds to a corneal surface of the eye. In still other examples, the flanged surface 150 may have a curvature, part of which corresponds to a sclera surface and another part corresponds to a corneal surface. In this way, the flanged surface 150 may be concave. In other examples, the flanged surface 150 may be flat. In still other examples, the flanged surface 150 may be convex. Furthermore, the flanged surface 150 can have any desired contour. For example, flanged surface 150 may be a curved surface that has radii of curvature that vary along radial directions other than a center of flanged surface 150. In still other examples, flanged surface 150 may define a surface that has variant curvature along different radial directions, as well as curvature that varies along one or more particular radial directions.

[0046] In Figure 3, the insertion depth guard 140 is shown as a continuous feature forming a continuous flanged surface 150. In some implementations, the insertion depth guard 140 may be segmented into a plurality of features or protrusions that form a plurality of eye-contacting surfaces. These eye contact surfaces can work together to control the depth to which the nozzle 120 can penetrate an eye. In other deployments, insertion depth protection 140 may be omitted.

[0047] An exemplary implementation of the insertion depth guard 140 is shown in Figures 6 to 7. In Figure 6, the IOL injector 10 is shown with the nozzle 120 inserted into an eye 151 through a wound 152 formed in the eye . Thus, as explained above, the flanged surface 150 of the insertion depth shield 140 may be spherical in nature in order to conform to the eye 151 when the nozzle 120 is fully inserted therein.

[0048] Figure 7 shows a side view of the distal portion of the IOL injector 10 showing an exemplary model for defining a flanged surface shape 150. In this illustrated example, the surface is defined as spherical in nature. Thus, in some examples, the flanged surface can be described as a “spherical surface” which is understood to mean a surface that conforms to a sphere. A spherical surface of the flanged surface 150 can approximate the shape of an eye. However, a spherical surface is provided as an example only. Thus, the shape of the flanged surface 150 can be any shape desired.

[0049] As shown, a center 153 for use in defining a spherical surface of the flange surface 150 may be located with respect to the nozzle 120 of the IOL injector 10. A center 153 of the spherical surface may be located to produce, for example, example, a desired length 154 of nozzle 120 extending beyond flanged surface 150 and thereby into an eye.

[0050] Injector body 20 may include a tapered portion 155. Nozzle 120 and tapered portion 155 meet at a location 156. A horizontal position of center 153 may be made with reference to location 156. For example, an offset horizontal 157 from center 153 from location 156 may be in the range of 7.6 mm to 8.0 mm. Accordingly, in some deployments, the hub 153 may have a horizontal offset of 7.6mm, 7.7mm, 7.8mm, 7.9mm, or 8.0mm. A vertical position of center 153 may be defined by a vertical distance 158 from longitudinal axis 75. In some examples, vertical offset 158 may be from 2.3 mm to 2.7 mm. Thus, in some deployments, the hub 153 may have a horizontal offset of 2.3mm, 2.4mm, 2.5mm, 2.6mm, or 2.7mm. However, it is noted that the ranges of horizontal shift 157 and vertical shift 158 from center 153 are provided as examples only. Thus, the values of horizontal offset 157 and vertical offset 158 from center 153 may be greater or lesser than the examples provided or any value in between. Furthermore, the horizontal offset 157 and the vertical offset 158 can be any desired length.

[0051] In some deployments, a radius 159 of spherical surface 160 can be scaled to match a radius of an eye. In some examples, the radius 159 may be within the range of 7.5mm to 8.1mm. Thus, the radius can be 7.5mm, 7.6mm, 7.7mm, 7.8mm, 7.9mm, 8.0mm or 8.1mm. These values are provided as examples only. Consequently, it is within the scope of the description that the radius 159 may be greater or lesser than the given values or any value in between. Consequently, the radius value 159 can be any desired value.

[0052] The values of horizontal offset 157, vertical offset 158 and radius 159 can be selected to produce a nozzle length 154 of any desired size. For example, in some examples, these values can be selected to produce a nozzle length 154 of between 1.0 mm and 5.0 mm. In some implementations, the length of the nozzle 120 may be 2.0 mm. In other examples, the length of the nozzle 120 may be 3.0 mm. In some examples, nozzle 120 may be 4.0. In still other examples, the length of the nozzle 120 may be 5.0 mm. However, the scope of the description is not limited in this way. Instead, the length of nozzle 120 may be longer or shorter than the values shown or any value in between. Furthermore, the length of the nozzle 120 can be any desired length.

[0053] Figure 8 shows a detailed cross-sectional view of housing 80 and a portion of the hole 40 of the exemplary nozzle body 20 shown in Figure 2. The hole 40 is defined by an interior wall 298. The interior wall 298 includes a tapered portion that includes a first tapered wall 301 and a second tapered wall 303. The tapered portion of the inner wall 298 defines an opening 170 at an interface 172 between the hole 40 and the housing 80. The opening 170 includes a height H1. Distal end portion 211 of piston rod 210 has a height of H2. In some examples, height H1 may be greater than height H2, so that, initially, there is no interference between piston rod 210 and interior wall 298 in opening 170. In other examples, height H1 may be equal to or greater than height H2 so that piston rod 210 and opening 170 initially have an interference fit. In some implementations, the first tapered wall 301 includes a flexible wall portion. In the example shown, flexible wall portion 162 is a flexible portion that extends obliquely from inner wall 298, and particularly from first tapered wall 301. As shown in Figure 9, in some examples, portions of first tapered wall 301 are removed, which form voids 163 that intersect the flexible wall portion 162. Thus, in some examples, the flexible wall portion 162 may extend in a cantilevered manner.

[0054] Referring again to Figure 8, in some examples, the flexible wall portion 162 may be reclined toward the distal end 60 of the nozzle body 20. In some examples, an angle B defined by the flexible wall portion 162 and along the longitudinal axis 75 can be in the range of 20° to 60°. For example, in some examples, angle B may be 20°, 25°, 30°, 35°, 40°, 45°, 50°, 55° or 60°. Furthermore, angle B can be larger or smaller than the defined range or any size within the quoted range. Also, the scope of description is not limited in this way. Thus, angle B can be any desired angle.

[0055] Injector body 20 may also include a contour ramp 180 formed along an interior receiving surface 190 of housing 80. Generally, interior receiving surface 190 is the surface on which an IOL, such as IOL 70, is placed when loaded into the IOL injector 10. Figure 9 is a perspective view of a portion of the exemplary injector body 20 shown in Figure 2. Port 90 is not shown. In some examples, a vertical distance C between a tip of flexible wall portion 162 and the top of contour ramp 180 may correspond to a height H2 of a distal end portion 211 of plunger rod 210. In other examples, the distance C may be greater or less than the height H2 of the distal end portion 211 of the plunger rod 210. The flexible wall portion 162 and the contour ramp 180 are discussed in greater detail below.

[0056] As also shown in Figure 9, the nozzle body 20 may include a contour surface 192 that is offset from the receiving surface 190. A wall 194 is formed adjacent the contour surface 192. A freely extending end 452 of a haptic part 450 makes contact with the contour surface 192 when the IOL 70 is received in the compartment 80.

[0057] Referring to Figures 1 and 10 to 11, the plunger 30 may include a body portion 200, a plunger rod 210 extending distally from the body portion 200, and a plunger tip 220 formed at a distal end 230 of the plunger rod 210. The plunger 30 may also include a flange 240 formed at a proximal end 250 of the body portion 200. A tilting member 260 may be disposed on the plunger 30. In some examples, the tilting member 260 may be a spring. In some implementations, the tilting member 260 may be disposed adjacent the flange 240. A proximal end 262 may be fixedly secured to the body portion adjacent the flange 240. In other examples, the tilting member 260 may be disposed in another location. along body portion 200. In still other implementations, tilting member 260 may be formed or otherwise disposed on nozzle body 20 and adapted to engage plunger 30 at a selected location during advancement of plunger 30 through of hole 40.

[0058] Flange 240 can be used in conjunction with tabs 110 to advance plunger 30 through nozzle housing 20. For example, a user can apply pressure to tabs 110 with two fingers while applying opposite pressure to flange 240 with the user's thumb. A surface of flange 240 may be textured to provide positive grip by a user. In some examples, the texture may be in the form of a plurality of grooves. However, any desired texture can be used.

[0059] The body portion 200 may include a plurality of transversely arranged ribs 270. In some examples, the ribs 270 may be formed on either a first surface 280 or a second surface 290 of the body portion 200. ribs 270 may be formed on only one of the first surface 280 and the second surface 290. A longitudinally extending rib 300 may also be formed on one or both of the first and second surfaces 280, 290.

[0060] In some examples, the body portion 200 may also include one or more protrusions 202, as shown in Figure 11. The protrusions 202 may extend longitudinally along a length of the body portion 200. The protrusions 202 may be grooves received 204 formed in the nozzle body 20, as shown in Figure 1. The protrusions 202 and the grooves 204 interact to align the plunger 30 within the bore 40 of the nozzle body 20.

[0061] Body portion 220 may also include centilever members 292. Centilever members 292 may extend from a proximal end 294 of body portion 200 toward distal end 250. Centilever members 292 may include flared portions 296. The centilever members 292 may also include substantially horizontal portions 297. The flared portions 296 are configured to engage the interior wall 298 of the injector body 20 which defines the bore 40, as shown in Figure 2. centilever 292 and the inner wall 298 generate a resistive force to the advancement of the plunger 30 and provide tactile feedback to the user during the advancement of the plunger 30. For example, in some implementations, the resistive force generated by the contact between the centilever members 292 and the inner wall 298 can provide a baseline resistance that resists the advance of the plunger 30.

[0062] In some examples, the piston rod 210 may include an angled portion 212. The distal end portion 211 may form part of the angled portion 212. The angled portion 212 may define an angle, A, within the range of 1° at 5° with longitudinal axis 75. In some examples, angle A may be 2°. In some examples, angle A may be 2.5°. In still other examples, angle A may be 3°, 3.5°, 4°, 4.5° or 5°. Furthermore, although the above values of A are given as examples, the angle A can be greater or less than the indicated range or any value in between. Thus, angle A can be any desired angle.

[0063] Angled portion 212 ensures that plunger tip 220 contacts and follows receiving surface 190 as plunger 30 is advanced through bore 40. Particularly, the angle A defined by angled portion 212 exceeds what is required to cause plunger tip 220 to contact inner wall 298 of bore 40. That is, when plunger 30 is disposed within bore 40, engagement between plunger tip 220 and inner wall 298 causes that the angled portion 212 twists inwardly due to angle A. Accordingly, the angled portion 212 ensures that the plunger tip 220 properly engages the haptics and optics of an IOL that is inserted from the IOL injector 10. This is described in more detail below. Although the angled portion 212 is shown as a substantially straight portion twisted at an angle relative to the remainder of the piston rod 210, the scope is not limited in this way. In some examples, a portion of the piston rod 210 may have a continuous curvature. In other examples, an entire length of piston rod 210 may be bent or curved. Furthermore, the amount of angular deviation from the longitudinal axis 75 or the amount of curvature can be selected in order to provide a desired amount of engagement between the plunger tip 220 and the interior surfaces of the nozzle body 20.

[0064] Tilt member 260 may be affixed to body portion 200 adjacent flange 240. In some examples, tilt member 260 may form a loop 310 that extends distally along body portion 200 that functions as a spring to resist advancement of plunger 30 when lug 310 engages nozzle body 20. Tilt member 260 may also include collar channel 320 261 through which body portion 200 extends. Thus, in operation, as the plunger 30 is advanced through the hole 40 of the nozzle body 20 (i.e., in the direction of the arrow 330), a distal end 265 of the tilting member 260 contacts the proximal end 50 of the injector body 20 at a selected location along the stroke of the plunger 30. As the injector 30 is further advanced, the tilting member 260 is compressed and the channel 320 allows the distal end 265 of the tilting member 260 to move relative to body portion 200. Similarly, channel 320 allows relative movement between body portion 200 and distal end 265 of tilt member 260 during proximal movement of plunger 30 (i.e., in the direction of the arrow). 340).

[0065] The tilting element 260 in the form of a ring 310, shown, for example, in Figure 2, is provided merely as an example. Tilt element 260 can have other configurations. For example, Figure 16 illustrates a tilting member having elongated elliptical or oval members 1600 disposed on opposite sides of the body portion 200 of plunger 30 and secured to flange 240. Figure 17 shows another exemplary configuration of tilting member 260. Figure 17, the tilt member 260 is in the form of curved centilever members 1700 provided on opposite sides of the body portion 200 of the plunger 30. The centilever members 1700 are secured to the flange 240. Figure 18 shows an example in which the member The tilting element 260 is integrated into the body portion 200 of the plunger 30. The tilting member 260 includes arcuate members 1800 that engage an interior wall that defines the bore 40 of the nozzle body 20. Although some examples are provided, the scope of the description is not limited to these. Instead, slope elements that have other shapes and configurations are included in the scope of the description.

[0066] Referring to Figures 2, 11 and 12, the IOL injector 10 may also include a plunger lock 350. The plunger lock 350 is removably disposed in a groove 360 formed in one of the tabs 110 Plunger latch 350 includes a protrusion 370 formed at one end thereof. Plunger lock 350 may include a single protrusion 370, as shown in Figure 2. In other examples, plunger lock 350 may include a plurality of protrusions 370. For example, Figure 12 illustrates an exemplary plunger lock 350 which has two protrusions 370. In other examples, the plunger lock 350 may include additional protrusions 370.

[0067] When installed, the protrusion 370 extends through a hole 375 formed in the nozzle body 20 and is received in a gap 380 formed in the plunger 30. When the plunger lock 350 is installed, the protrusion 370 and the gap 380 interlock to prevent plunger 30 from moving within bore 40. That is, installed plunger lock 350 prevents plunger 30 from being advanced through or removed from bore 40. Upon removal of plunger lock 350, plunger 30 may be advanced freely through bore 40. In some examples, plunger latch 350 may include a plurality of raised ribs 390. Ribs 390 provide tactile resistance to aid in removal of and insertion into groove 360.

[0068] Plunger latch 350 may be U-shaped and define a channel 382. Channel 382 receives a portion of tab 110. In addition, when engaged with tab 110, a proximal portion 384 of plunger latch 350 can be flexed to outside. Consequently, the plunger lock 350 may be frictionally retained on the tab 110.

[0069] Referring to Figures 2 and 10, in some implementations, body portion 20 may include shoulders 392 formed in hole 40. Shoulders 392 may be formed at a location in hole 40 where hole 40 tapers from of an enlarged proximal portion 394 and a narrower distal portion 396. In some examples, the shoulder 392 may be a curved surface. In other examples, shoulder 392 can be defined as a staggered change in hole size 40.

[0070] The centilever members 292 may engage the shoulder 392. In some deployments, the flared portion 296 of the centilever members 292 may engage the shoulder 392. In some examples, a location in which the centilever members 292 engage the shoulder 392 may be one in which the gap 380 aligns with the hole 375. Thus, in some implementations, the engagement between the centilever members 292 and the shoulder 392 may provide a convenient arrangement for inserting the plunger latch 350 to lock the plunger 30 in place relative to injector body 20. In other deployments, gap 380 and orifice 375 may not align when centilever members 292 engage shoulder 392.

[0071] As the plunger 30 is advanced through the hole 40, the flared portion 296 of the centilever members 292 can be displaced inwardly to follow the narrowed distal portion 396 of the bore 40. As a result of this deflection of the flared portion 296, the centilever members 292 apply an increased normal force to the inner wall 298 of the hole 40. This increased normal force generates a frictional force that resists the advancement of the plunger 30 through the hole 40, thereby providing tactile feedback to the user.

[0072] Referring to Figures 1 and 2, the IOL injector may also include an IOL stop 400. The IOL stop 400 is received in a recess 410 formed in an outer surface 420 of port 90. IOL 400 may include a protrusion 430 that extends through an opening 440 formed in the door. The protrusion 430 extends between the haptic part and the optics part of an IOL loaded in the housing 80. As shown in Figures 1 and 27, the IOL 70 includes haptics 450 and an optical part 460. The protrusion 430 is disposed between one of the haptics 450 and the optics 460. The IOL stop 430 may also include a tab 435. The tab 435 may be secured by a user for removing the IOL stop 430 from the injector body 20.

[0073] IOL stop 400 may also include a hole 470. Hole 470 aligns with another opening formed in port 90, e.g. opening 472 shown in Figure 19. Hole 470 and second opening 472 in port 90 form a passageway through which a material, such as a viscoelastic material, can be introduced into compartment 80.

[0074] IOL stop 400 is removable from port 90. When installed, IOL stop 400 prevents IOL advancement, such as IOL 70. Particularly, if IOL 70 advancement is attempted, optical part 460 enters in contact with the protrusion 430, thus preventing the advancement of the IOL 70.

[0075] Figure 13 shows an exemplary plunger tip 220. Plunger tip 220 may include a first protrusion 480 and a second protrusion 490 extending from opposite sides. The first and second protrusions 480, 490 define a first groove 500. The first groove 500 defines a surface 502. The second groove 510 is formed within the first groove 500. The first groove 500, particularly in combination with the first protrusion 480, works to capture and bend a back haptic part of an IOL. The second groove 510 functions to capture and bend an optical part of an IOL.

[0076] A side wall 520 of the plunger tip 220 may be tapered. Tapered sidewall 520 can provide a location space for a reinforced portion of the rear haptic portion of an IOL. The reinforced portion of the haptic part tends to remain proximal to the optic part of the IOL. In this way, the tapered sidewall 520 can provide a locating space that promotes proper folding of the IOL during delivery to an eye.

[0077] Figures 28 to 30 show another exemplary plunger tip 220. This plunger tip 220 includes a first protrusion 600, a second protrusion 602, and a groove 604. The first protrusion extends at an angle. oblique θ from longitudinal axis 606. In some examples, angle θ may be between 25° to 60°. In other examples, the angle θ can be less than 25° or greater than 60°. In other examples, the angle θ can be between 0° to 60°. In still other deployments, the angle θ may be between 0° and 70°; 0° and 80°; or 0° and 90°. Generally speaking, the angle θ can be selected to be any desired angle. For example, angle θ may be selected based on one or more of the following: (1) a size, such as a height, of orifice 64 formed within nozzle 60; (2) the height of compartment 80; (3) how the height of orifice 64 and/or housing varies along their respective lengths; and (3) the thickness of the plunger tip 220. The second protrusion 602 may include a tapered portion 608. The tapered portion 608 is operable to engage an optical portion of an IOL, such as an optical portion 460 shown in Figure 27. A optics can slide along the tapered surface so that the optics can be moved into the groove 604. As a result, the second protrusion 602 is positioned adjacent a surface of the optics.

[0078] The exemplary plunger tip 220 shown in Figures 28 to 30 also includes a surface 610 that may be similar to surface 502. Surface 610 is adapted to contact and displace a haptic part that is posterior or extending from proximally, such as haptic part 450 shown in Figure 27, so that the haptic part is bent. In some examples, surface 610 may be a flat surface. In other examples, the surface 610 may be the curved or otherwise contoured surface. Exemplary plunger tip 220 may also include a sidewall 612 and bearing surface 613. Similar to sidewall 520, sidewall 612 may be tapered, as shown in Figure 30. In some examples, sidewall 612 may include a first curved portion 614. The first curved portion 614 may receive a twisted portion of the rear haptic portion that remains proximal to the optic portion during folding. The posterior haptic is supported by the bearing surface 613 during the bending process. Sidewall 612 may also include a second curved surface 615.

[0079] The first obliquely extending protrusion 600 effectively increases a height H2 compared to a plunger tip 220 shown in Figure 13, for example. This increased height H2 enhances the ability of plunger tip 220 to capture the posterior haptic during an advance of plunger 30. In operation, as plunger 30 is advanced distally, distal end 618 engages an interior wall of the plunger. dispensing port 127 due to changes in the height H1 of dispensing port 127. As the height H1 decreases, the first protrusion 600 pivots about the hinge 620, effectively reducing the overall height H2 of the plunger tip 220. that the first protrusion 600 pivots about the hinge 620 and rotates in a direction toward the second protrusion 602, the first protrusion 600 captures the posterior haptic portion between the optical portion of the IOL and the first protrusion 600. Therefore, with the first protrusion 600 protrusion 600 pivotable around hinge 620, plunger tip size 220 has the ability to adapt and conform to the change in height H1 of delivery port 127 as the IOL is advanced distally and bent.

[0080] Figure 14 shows an interior surface 530 of the port 90. The surface 510 may include a lip 530. The lip 530 may include a curved portion 540. In the illustrated example, the curved portion 540 extends proximally and inwardly. toward longitudinal axis 75. Curved portion 540 is configured to overlap a portion of a rear haptic portion of an IOL, which provides proper bending for the IOL when plunger 30 is advanced through nozzle body 20.

[0081] In operation, plunger lock 350 may be inserted into groove 360 to lock plunger 30 in position relative to injector body 20. An IOL, such as IOL 70, may be loaded in slot 80. For example , port 90 can be opened by a user and a desired IOL inserted into slot 80. Door 90 can be closed by inserting the IOL into slot 80. In some examples, an IOL may be preloaded during manufacture .

[0082] The IOL stop 400 can be inserted into the recess 410 formed in the port 90. The viscoelastic material can be introduced into the compartment 80 through the aligned hole 470 and the corresponding opening formed in the port 90. The viscoelastic material functions as a lubricant for promote the advancement and folding of the IOL during the advancement and distribution of the IOL in one eye. In some examples, the viscoelastic material may be introduced into compartment 80 at the time of manufacture.

[0083] IOL stop 400 can be removed from recess 410 formed in port 90 and plunger lock 350 can be removed from groove 360. Plunger 30 can be advanced through hole 40. Sliding engagement between centilever members 292 and the interior wall 298 of the nozzle body 20 generates a resistive force that resists the advancement of the plunger 30. In some examples, the plunger 30 may be advanced through the hole 40 until the plunger tip 220 extends into the housing. 80. For example, plunger 30 may be advanced until plunger tip 220 is adjacent to or in contact with the IOL. In other examples, the plunger 30 may be advanced through the bore 40 so that the IOL is partially or completely bent. Furthermore, plunger 30 may advance the IOL to a position within the nozzle shortly after it is ejected from distal opening 125. For example, in some examples, advancement of plunger 30, prior to insertion of nozzle 120 into a wound formed in the eye, can be stopped at the point where the distal end 265 of the tilting member 260 contacts the proximal end 50 of the injector body 20, as shown in Figure 15.

[0084] The advancement of the plunger 30 through the nozzle body 20 is discussed below with reference to Figures 1, 8 and 13. In some examples, dimensional tolerances between the plunger 30 and the nozzle body 20 may allow relative movement between the plunger 30 and the nozzle body 20 so that the distal end portion 211 has the ability to move within the hole 40 in the direction of arrows 471, 472 (hereinafter referred to as "tolerance movement"). In the examples, particularly those in which the plunger 30 includes an angled portion 212, the plunger tip 220 normally remains in contact with the interior wall 298 even if the plunger 30 undergoes tolerance movement as the plunger 30 is advanced through the bore 40. Thus, in some examples, despite any forbearance movement, plunger tip 220 remains in contact with inner wall 298. Accordingly, second tapered wall 303 directs and centers plunger tip 220 into opening 170.

[0085] If plunger 30 undergoes tolerance movement so that plunger tip 220 is no longer in contact with inner wall 298 of bore 40, first tapered wall 301, which includes flexible wall portion 162, directs and centers the plunger tip 220 to the opening 170 formed in the interface 172, resulting in contact between the plunger tip 220 and the second tapered wall 303. When the plunger 30 becomes fully engaged with the nozzle body 20, the tolerance movement will be substantially reduced or eliminated, ensuring that the plunger tip 220 remains engaged with the second tapered wall 303 and contour ramp 180. In some examples, complete engagement between the plunger 30 and the nozzle body 20 occurs when the members in centilever 292 are fully engaged with the inner wall 298 of hole 40. Consequently, in examples where tolerance movement may exist, upon complete engagement between piston 30 and nozzle body 2 0, the flexible wall portion 162 no longer influences the position of the plunger 30. However, once the plunger tip 220 is advanced through the opening 170, the flexible wall portion 162 no longer affects the directional trajectory of the plunger. 30 nor any part of it.

[0086] As the plunger tip 220 is advanced through the housing 80 in sliding contact with the receiving surface 190, the first groove 500 of the plunger tip 220 is positioned to engage the rear haptic part of the IOL, such as the posterior haptic 450 of IOL 70, as shown in Figure 8. As plunger tip 220 is advanced further, plunger tip 220 contacts contour ramp 180 and is forced vertically toward port 90. This vertical displacement of the plunger tip 220, while remaining in contact with the receiving surface 190, both bends the rear haptic portion upward over the optics of the IOL and aligns the second groove 510 of the plunger tip 220 with a trailing edge of the IOL. haptic part. Particularly, surface 502 of plunger tip 220 contacts and displaces haptic portion 450 as plunger tip 220 is passed along contour surface 180, thereby folding back haptic portion 450. Back haptic 450 folds over, contour surface 192 and wall 194 work together to both locate the freely extending end 452 of rear haptic 450 above and over optics 460. Contour surface profile 192 operates to suspend rear haptic 450 as plunger tip 220 is displaced toward distal end 60 of injector body 20. Wall 194 restricts lateral movement of freely extending end 452 of rear haptic portion 450, which causes causing the haptic portion to move distally with respect to the optic portion 460. Accordingly, the rear haptic portion 450 is both raised above and folded over the optic portion. 460 as the plunger tip 220 contacts the trailing haptic 450 and travels along the contour ramp 180. Since the plunger tip 220 is further advanced, the second groove 510 accepts the trailing edge of the optics 460, and the plunger tip 220 is displaced vertically in the opposite direction of port 90 due to a combination of influences from both the downward slope of contour ramp 180 and the angled portion 212 of plunger rod 210. Movement of plunger tip 220 in the manner described provides IOL 70's improved engagement and folding.

[0087] Figure 19 is a detailed view of a portion of the distal end 60 of the nozzle body 20. The distal end 60 includes a tapered portion 62 and the insertion depth guard 140. The distal end 265 of the Tilt 260 may engage proximal end 50 of injector body 20 to define a folded or partially folded IOL pause location. Nozzle 120 may include a demarcation 1900 that provides a visual indication of the pause position. For example, in the example shown in Figure 19, the demarcation 1900 is a narrow rim or narrow line that encircles all or a portion of the distal end 60. In some examples, the demarcation 1900 may be disposed between the tapered portion 62 and the shield guard. insertion depth 140. At least a portion of the injector body 20 may be formed from a transparent or semi-transparent material that allows a user to see an IOL within the injector body 20. Particularly, the distal end 60 of the injector body 20 may be formed from a transparent material to allow observation of the IOL as it is moved therein by plunger 30.

[0088] Figure 20 shows a view of the distal end 60 of the IOL injector 10 with IOL 70 located therein in a paused position. As shown in Figure 20, the IOL pause position may be defined as a location where the distal edge 462 of the optic portion 460 of the IOL 70 substantially aligns with the demarcation 1900. A haptic portion 450 or a portion thereof may extend beyond demarcation 1900. Again, the pause position may also correspond to the initial engagement of the distal end 265 of the tilt element 260 with the proximal end 50 of the injector body 20. Therefore, the pause location may be indicated together by positioning it. the IOL, or part thereof, with respect to demarcation 1900 and initial contact between distal end 265 of tilt member 260.

[0089] In other examples, an IOL location relative to the distal opening 12 of the nozzle 120 when the distal end 256 of the tilting member 260 is in contact with the proximal end 50 of the nozzle body 20 may vary. In some examples, the IOL may be partially ejected from the distal opening 125 when the distal end 265 of the tilting member 260 contacts the proximal end 50 of the injector body 20. For example, in some examples, approximately half of the IOL may be ejected from the distal opening 125 when the distal end 256 of the tilting member 260 contacts the proximal end 50 of the injector body 20. In other examples, the IOL may be contained entirely within an IOL injector when the distal end 256 of the tilting member 260 makes contact with the proximal end 50 of the injector body 20.

[0090] Figure 21 shows a cross-sectional view of aperture 170 formed at interface 172. In some examples, aperture 170 may define a "T" shape. Plunger tip 220 is shown disposed in opening 170 with flexible wall portion 162 in contact with a surface 214 of plunger rod 210. In some examples, the cross-section of plunger rod 210 increases toward the proximal end of the rod. piston rod 210. Thus, as piston rod 210 is advanced through opening 170, piston rod 210 fills the opening as a result of the increasing cross-section. Portions 173 and 175 of opening 170 are filled by flanges 213, 215 (shown in Figure 11).

[0091] As the opening 170 is filled by the increasing cross-section of the plunger rod 210 as the plunger rod 210 is advanced distally through the nozzle body 20, the flexible wall portion 162 is flexed in the direction of the arrow. 471 to allow passage of the plunger rod 210, as shown in Figure 22. Furthermore, as a result of the angled portion 212 of the plunger rod 210, the contour ramp 180, and the bending of the IOL 70 as it is advanced through an injector. of IOL 10, plunger tip 220 is pushed along a defined path through housing 80, distal end 60 and nozzle 120 uninfluenced by flexible wall portion 162.

[0092] Figure 22 shows the flexible wall portion 162 that is flexed in the direction of 471 as the plunger rod 210 continues to be advanced distally through the IOL injector 10. In addition, Figure 22 also shows the tip of plunger 220 engages with IOL 70 so that rear haptic portion 450 is received in first groove 500 at a location offset from second groove 510, and the proximal edge of optic portion 460 is received in second groove 510.

[0093] As the IOL 70 is advanced through the passage 64 of the distal end 60, the IOL 70 is folded into a reduced size to allow the passage of the IOL 70 through the nozzle 120 and into the eye. During the bending of the IOL 70, a resistive force on the plunger 30 is increased. Once the IOL 70 is completely bent 70, the resistive force on the plunger 30 generally reduces.

[0094] A sore may form in the eye. The wound may be sized to accommodate the nozzle 120 of the IOL injector 10. The nozzle 120 may be inserted into the wound. The nozzle 120 may be advanced through the wound until the flanged surface 150 of the insertion depth shield 140 is contiguous with the outer surface of the eye. Contact between the insertion depth shield 140 and the outer surface of the eye limits the depth to which the nozzle 120 can be inserted into the eye, preventing unnecessary strain on the wound edges as well as preventing wound enlargement due to overinsertion. of the IOL injector 10. Accordingly, the insertion depth guard 140 operates to reduce additional trauma to the eye and wound enlargement.

[0095] With the nozzle properly positioned inside the eye through the wound, the user can complete the delivery of the folded IOL into the eye. Referring again to Figure 15, as the advancement of the plunger 30 continues, the tilt element 260 is compressed (indicated by the dotted outline of the tilt element 260). Compression of tilt element 260 increases a resistive force for advancing piston 30, also called immersion force. This additional resistance to the advancement of the plunger 30 lessens the changes in immersion force associated with bending the IOL prior to insertion into the eye. Furthermore, in some examples, the tilt element 260 may be brought into contact with the injector body 120 when, or close to when, the IOL 70 is completely bent so that a reduction in resistive force that may result from the IOL 70 is fully bent can be deflected by the compression of the tilt element 260. This increase in resistive force provided by the compression of the tilt element 260, particularly in light of a reduction that can result due to the IOL 70 being completely bent, provides improved tactile feedback to a user, such as a medical professional, while delivering the IOL 70 into one eye. This improved tactile feedback provides the user with improved control during the delivery of the IOL 70, which can prevent the IOL 70 from being rapidly expelled to the eye.

[0096] As a result, the user has the ability to provide a smooth application of force without experiencing any sudden or rapid changes in plunger 30 advance. Such sudden or rapid changes can result in the IOL being expelled quickly from an injector. Rapid expulsion of an IOL into an eye can cause damage, such as perforation of the capsular bag. Such damage may increase the time required to complete the surgical procedure and may increase immediate or postoperative harm to the patient. Upon insertion of the IOL into the eye, an IOL 10 injector can be withdrawn from the eye.

[0097] Figures 23 to 26 show exemplary feed stops operable to prevent tilt element 260 from actuation. For example, in some examples, exemplary feed stops are operable to prevent tilt element compression 260 and preventing the advancement of the plunger 30 through the nozzle body 20 beyond a selected amount. Referring to Figures 23 and 24, an advance stop 2300 is shown coupled to the body portion 200 of the plunger 30 between the flange 240 and the collar 261 of the tilt element 260. The advance stop 2300 can be moved into engagement. with plunger 30 laterally in the direction of arrow 2310. Similarly, feed stop 220 can be removed from plunger 30 by moving feed stop 2300 laterally in the direction of arrow 2320. Feed stop 2300 can be retained in the plunger 30 such as by a frictional engagement and/or detent between one or more portions of plunger 30 and advance stop 2300. A user may manipulate advance stop 2300 by means of a tab 2330 formed therein. Feed stop 2300 may be formed from a rigid material, such as a polymer, composite material, metal, or any other suitable material.

[0098] The inclusion of advance stop 2300 on plunger 30 prevents actuation of tilt element 260 and further advancement of plunger 30 through nozzle body 20 when distal end 265 of tilt member 260 contacts the end 50 of the injector body 20. Any force acting on the distal end 265 of the tilting member 260 is transmitted from the collar 261 through the advance stop 2300 and to the flange 240. In some examples, the inclusion of the 2300 feed can be useful to prevent an IOL from ejecting suddenly from the IOL 10 injector due to, for example, excessive forces applied to an IOL 10 injector by the user. In other examples, feed stop 2300 may be included to ensure that the IOL advance stops upon reaching a selected location within the IOL injector 10. For example, advance stop 2300 can prevent advance additional IOL once the IOL has reached the pause position. However, a feed stop, such as the feed stops described in this document, need not be included or otherwise used with the IOL 10 injector.

[0099] Figures 25 to 26 illustrate another exemplary implementation of a feed stop. Exemplary feed stop 2500 is shown coupled to plunger 30. Feed stop 2500 includes a central member 2510 with arc-shaped wings 2520 extending therefrom. The central member 2510 has an arcuate cross-section that is received in the body portion 200 of the plunger 30. The arc shape of the wings 2520 can conform or substantially conform to the shape of the tilt element 260. The advance stop 2500 can be retained. on the plunger 30 such as by a frictional engagement and/or a detent between one or more portions of the plunger, for example the tilting member 260 and/or the body portion 200, to name a few examples, and the advance stop 2500, for example, the surfaces of the feed stop 2500 contiguously with the tilt element 260, the collar 261 and/or the flange 240, to name a few examples. Feed stop 2500 may be formed from a rigid material, such as a polymer, composite material, metal, or any other suitable material.

[00100] Feed stop 2500 can operate similarly to feed stop 2300. When coupled to plunger 30, feed stop 2500 limits the amount of plunger 30 that can be displaced within injector body 20. In some examples , when the plunger 30 has been displaced within the nozzle body 20 by the selected amount, a distal end of the central member 2510 contacts the proximal end 50 of the nozzle body 20. The central member 2510 transmits any force to the flange 240, thereby preventing actuation of the tilting member 260. In other examples, the collar 261 may contact the proximal end 50 of the injector body 20. However, the close engagement between the tilting member 260 and the wings of compliance 2520 prevents the tilting element 260 from bending outward, thereby preventing the tilting element 260 from actuation.

[00101] Although the description provides several examples, the scope of the present description is not limited in this way. Rather, a wide range of modifications, alterations and substitutions are contemplated in the aforementioned description. It should be understood that such variations may be made to the aforementioned without departing from the scope of the present description.

Claims (6)

1. An intraocular lens injector comprising: an injector body (20) comprising: a hole (40) defined by an interior wall, the hole (40) extending from a proximal end (50) of the injector body (20) to a distal end (60) of the nozzle body (20) along a longitudinal axis; a nozzle (120) at the distal end (60) of the nozzle body (20), wherein a distal opening (125) is formed in the nozzle (120); a compartment (80) configured to house an IOL prior to insertion into an eye; a hole (64) in the distal end (60) of the nozzle body (20); wherein the housing (80), the distal end (60) of the injector body (20) including the passage (64), and the opening (125) define a dispensing orifice (127); wherein the height of the hole (40) in the delivery hole (127) varies over a length of the delivery hole; an insertion depth guard (140) disposed at a distal end of the injector body (20), characterized in that the insertion depth guard (140) comprising a flanged surface (150); and the nozzle (120) distally extending beyond the insertion depth guard (140); and a plunger (30) slidable in the bore (40), the plunger (30) including a body portion (200), a plunger rod (210) and a plunger tip (220) formed at a distal end (230). ) of the piston rod (210) further comprising: wherein the piston rod (120) is substantially straight from a proximal end of the piston rod to a distal end (211) of the piston rod with an angled portion (212) proximate the distal end (211) of the plunger rod; wherein the plunger tip (220) is configured to slide through the dispensing hole (127) of the injector body (20) and into the nozzle (120) of the injector body (20); wherein the angled portion (212) on the plunger rod (120) causes the plunger tip (220) to interface with the inner wall (298) when the plunger tip (220) is slid into the plunger hole. distribution (127) of the nozzle body (20); wherein the plunger tip (220) includes a first protrusion (480) and a second protrusion (490) extending from opposite sides, the first and second protrusions (480, 490) defining a first groove (500), the first groove (500) defining a surface (502) and wherein a second groove (510) is formed within the first groove (500), wherein the first groove (500), in combination with the first protrusion (480), serves to engage a haptic part of an IOL and wherein the second groove (510) functions to capture and bend an optical part of an IOL; wherein the groove (500) of the plunger tip (220) engages an optical portion of the IOL as the plunger is advanced through the delivery hole (127), and wherein the variation in height of the delivery hole (127) causes the IOL to bend as the plunger is advanced through the delivery hole. 2. Intraocular lens injector, according to claim 1, characterized in that the injector body additionally comprises: a flap (110) formed at a proximal end thereof; a groove (360) that extends through the tab (110); and a hole (375) aligned with the groove (360). 3. Intraocular lens injector, according to claim 2, characterized in that it additionally comprises a plunger lock (350) comprising a protrusion (370), wherein the plunger lock (350) is detachably received in the groove (360) so that the protrusion (370) extends through the hole (375) and into a gap (380) formed in the plunger. 4. Intraocular lens injector, according to claim 3, characterized in that the plunger comprises a centilever member, in which the hole (40) comprises a shoulder (392), and the hole formed in the injector body ( 20) lines up with the gap (380) formed in the plunger when the centilever member engages the shoulder (392). 5. Intraocular lens injector device, according to claim 1, characterized in that the plunger comprises a centilever member and in which the centilever member deflectively engages the inner wall of the hole (40) as the plunger is advanced through hole (40). 6. Intraocular lens injector according to claim 1, characterized in that it additionally comprises an advance stop detachably coupled to the plunger, the advance stop being adapted to limit an amount by which the plunger is allowed advance through hole (40).

Images